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CT215: Assembly Language Programming

CT215: Assembly Language Programming . Integer Arithmetic. Chapter Overview. Shift and Rotate Instructions Shift and Rotate Applications Multiplication and Division Instructions Extended Addition and Subtraction ASCII and Packed Decimal Arithmetic. Shift and Rotate Instructions.

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CT215: Assembly Language Programming

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  1. CT215: Assembly Language Programming Integer Arithmetic

  2. Chapter Overview • Shift and Rotate Instructions • Shift and Rotate Applications • Multiplication and Division Instructions • Extended Addition and Subtraction • ASCII and Packed Decimal Arithmetic

  3. Shift and Rotate Instructions • Logical vs Arithmetic Shifts • SHL Instruction • SHR Instruction • SAL and SAR Instructions • ROL Instruction • ROR Instruction • RCL and RCR Instructions • SHLD/SHRD Instructions

  4. Logical vs Arithmetic Shifts • A logical shift fills the newly created bit position with zero: • An arithmetic shift fills the newly created bit position with a copy of the number’s sign bit:

  5. SHL Instruction • The SHL (shift left) instruction performs a logical left shift on the destination operand, filling the lowest bit with 0. • Operand types for SHL: SHL reg,imm8 SHL mem,imm8 SHL reg,CL SHL mem,CL (Same for all shift and rotate instructions)

  6. Shifting left n bits multiplies the operand by 2n For example, 5 * 22 = 20 mov dl,5 shl dl,2 ; DL = 20 Fast Multiplication Shifting left 1 bit multiplies a number by 2 mov dl,5 shl dl,1

  7. Shifting right n bits divides the operand by 2n mov dl,80 shr dl,1 ; DL = 40 shr dl,2 ; DL = 10 SHR Instruction • The SHR (shift right) instruction performs a logical right shift on the destination operand. The highest bit position is filled with a zero.

  8. An arithmetic shift preserves the number's sign. mov dl,-80 sar dl,1 ; DL = -40 sar dl,2 ; DL = -10 SAL and SAR Instructions • SAL (shift arithmetic left) is identical to SHL. • SAR (shift arithmetic right) performs a right arithmetic shift on the destination operand.

  9. Your turn . . . Indicate the hexadecimal value of AL after each shift: mov al,6Bh shr al,1 a. shl al,3 b. mov al,8Ch sar al,1 c. sar al,3 d. 35h A8h C6h F8h

  10. Operand types for these instructions mem & reg can be any size SHL reg,imm8 SHL mem,imm8 SHL reg,CL SHL mem,CL So, the following are valid: SHL EAX,3 SHL valDW,5

  11. ROL Instruction • ROL (rotate) shifts each bit to the left • The highest bit is copied into both the Carry flag and into the lowest bit • No bits are lost mov al,11110000b rol al,1 ; AL = 11100001b mov dl,3Fh rol dl,4 ; DL = F3h

  12. ROR Instruction • ROR (rotate right) shifts each bit to the right • The lowest bit is copied into both the Carry flag and into the highest bit • No bits are lost mov al,11110000b ror al,1 ; AL = 01111000b mov dl,3Fh ror dl,4 ; DL = F3h

  13. Your turn . . . Indicate the hexadecimal value of AL after each rotation: mov al,6Bh ror al,1 a. rol al,3 b. B5h ADh

  14. RCL Instruction • RCL (rotate carry left) shifts each bit to the left • Copies the Carry flag to the least significant bit • Copies the most significant bit to the Carry flag clc ; CF = 0 mov bl,88h ; CF,BL = 0 10001000b rcl bl,1 ; CF,BL = 1 00010000b rcl bl,1 ; CF,BL = 0 00100001b

  15. RCR Instruction • RCR (rotate carry right) shifts each bit to the right • Copies the Carry flag to the most significant bit • Copies the least significant bit to the Carry flag stc ; CF = 1 mov ah,10h ; CF,AH = 1 00010000b rcr ah,1 ; CF,AH = 0 10001000b

  16. Your turn . . . Indicate the hexadecimal value of AL after each rotation: stc mov al,6Bh rcr al,1 a. rcl al,3 b. B5h AEh

  17. SHLD Instruction • Shifts a destination operand a given number of bits to the left • The bit positions opened up by the shift are filled by the most significant bits of the source operand • The source operand is not affected • Syntax: SHLD destination, source, count • Operand types: SHLD reg16/32, reg16/32, imm8/CL SHLD mem16/32, reg16/32, imm8/CL

  18. SHLD Example Shift wval 4 bits to the left and replace its lowest 4 bits with the high 4 bits of AX: .data wval WORD 9BA6h .code mov ax,0AC36h shld wval,ax,4 Before: After:

  19. SHRD Instruction • Shifts a destination operand a given number of bits to the right • The bit positions opened up by the shift are filled by the least significant bits of the source operand • The source operand is not affected • Syntax: SHRD destination, source, count • Operand types: SHRD reg16/32, reg16/32, imm8/CL SHRD mem16/32, reg16/32, imm8/CL

  20. SHRD Example Shift AX 4 bits to the right and replace its highest 4 bits with the low 4 bits of DX: Before: mov ax,234Bh mov dx,7654h shrd ax,dx,4 After:

  21. Your turn . . . Indicate the hexadecimal values of each destination operand: mov ax,7C36h mov dx,9FA6h shld dx,ax,4 ; DX = shrd dx,ax,8 ; DX = FA67h 36FAh

  22. Shift and Rotate Applications • Shifting Multiple Doublewords • Binary Multiplication • Displaying Binary Bits • Isolating a Bit String

  23. Shifting Multiple Doublewords • Programs sometimes need to shift all bits within an array, as one might when moving a bitmapped graphic image from one screen location to another. • The following shifts an array of 3 doublewords 1 bit to the right: .data ArraySize = 3 array DWORD ArraySize DUP(99999999h;1001 1001... .code mov esi,0 shr array[esi + 8],1 ; high dword rcr array[esi + 4],1 ; middle dword,include Carry rcr array[esi],1 ; low dword, include Carry

  24. Binary Multiplication • We already know that SHL performs unsigned multiplication efficiently when the multiplier is a power of 2. • You can factor any binary number into powers of 2. • For example, to multiply EAX * 36, factor 36 into 32 + 4 and use the distributive property of multiplication to carry out the operation: EAX * 36 = EAX * (32 + 4) = (EAX * 32)+(EAX * 4) mov eax,123 mov ebx,eax shl eax,5 ; mult by 25 shl ebx,2 ; mult by 22 add eax,ebx

  25. Your turn . . . Multiply AX by 26, using shifting and addition instructions. Hint: 26 = 16 + 8 + 2. mov ax,2 ; test value mov dx,ax shl dx,4 ; AX * 16 push dx ; save for later mov dx,ax shl dx,3 ; AX * 8 shl ax,1 ; AX * 2 add ax,dx ; AX * 10 pop dx ; recall AX * 16 add ax,dx ; AX * 26

  26. Displaying Binary Bits Algorithm: Shift MSB into the Carry flag; If CF = 1, append a "1" character to a string; otherwise, append a "0" character. Repeat in a loop, 32 times. .data buffer BYTE 32 DUP(0),0 .code mov ecx,32 mov esi,OFFSET buffer L1: shl eax,1 mov BYTE PTR [esi],'0' jnc L2 mov BYTE PTR [esi],'1' L2: inc esi loop L1

  27. Isolate the Month field: mov ax,dx ; make a copy of DX shr ax,5 ; shift right 5 bits and al,00001111b ; clear bits 4-7 mov month,al ; save in month variable Isolating a Bit String • The MS-DOS file date field packs the year, month, and day into 16 bits:

  28. Today • Continuing chapter 7 • Homework 5 out soon • Announcement: I’ll be traveling the week of 10/31-11/4, so Ahmed the TA will be lecturing.

  29. Multiplication and Division Instructions • MUL Instruction • IMUL Instruction • DIV Instruction • Signed Integer Division • CBW, CWD, CDQ Instructions • IDIV Instruction • Implementing Arithmetic Expressions

  30. Implied operands: MUL Instruction • The MUL (unsigned multiply) instruction multiplies an 8-, 16-, or 32-bit operand by either AL, AX, or EAX. • The resulting product is stored in parts of EAX & EDX registers • The instruction formats are: MUL r/m8 MUL r/m16 MUL r/m32

  31. 12345h * 1000h, using 32-bit operands: mov eax,12345h mov ebx,1000h mul ebx ; EDX:EAX = 0000000012345000h, CF=0 MUL Examples 100h * 2000h, using 16-bit operands: .data val1 WORD 2000h val2 WORD 100h .code mov ax,val1 mul val2 ; DX:AX = 00200000h, CF=1 The Carry flag indicates whether or not the upper half of the product contains significant digits.

  32. Your turn . . . What will be the hexadecimal values of DX, AX, and the Carry flag after the following instructions execute? mov ax,1234h mov bx,100h mul bx DX = 0012h, AX = 3400h, CF = 1

  33. Your turn . . . What will be the hexadecimal values of EDX, EAX, and the Carry flag after the following instructions execute? mov eax,00128765h mov ecx,10000h mul ecx EDX = 00000012h, EAX = 87650000h, CF = 1

  34. IMUL Instruction • IMUL (signed integer multiply ) multiplies an 8-, 16-, or 32-bit signed operand by either AL, AX, or EAX • Preserves the sign of the product by sign-extending it into the upper half of the destination register Example: multiply 48 * 4, using 8-bit operands: mov al,48 mov bl,4 imul bl ; AX = 00C0h, OF=1 OF=1 because AH is not a sign extension of AL. That is, AX = 0000 0000 1100 0000 and “0000 0000” is not a sign extension of “1”

  35. IMUL Examples Multiply 4,823,424 * -423: mov eax,4823424 mov ebx,-423 imul ebx ; EDX:EAX = FFFFFFFF86635D80h, OF=0 OF=0 because EDX is a sign extension of EAX. The value of OF means now “are you using the upper register?”

  36. Your turn . . . What will be the hexadecimal values of DX, AX, and the Overflow flag after the following instructions execute? mov ax,8760h mov bx,100h imul bx DX = FF87h, AX = 6000h, OF = 1

  37. Default Operands: DIV Instruction • The DIV (unsigned divide) instruction performs 8-bit, 16-bit, and 32-bit division on unsigned integers • A single operand is supplied (register or memory operand), which is assumed to be the divisor • Instruction formats: DIV r/m8 DIV r/m16 DIV r/m32 Recall: dividend / divisor

  38. Same division, using 32-bit operands: mov edx,0 ; clear dividend, high mov eax,8003h ; dividend, low mov ecx,100h ; divisor div ecx ; EAX = 00000080h, EDX = 3 DIV Examples Divide 8003h by 100h, using 16-bit operands: mov dx,0 ; clear dividend, high mov ax,8003h ; dividend, low mov cx,100h ; divisor div cx ; AX = 0080h, DX = 3

  39. Your turn . . . What will be the hexadecimal values of DX and AX after the following instructions execute? Or, if divide overflow occurs, you can indicate that as your answer: mov dx,0087h mov ax,6000h mov bx,100h div bx DX = 0000h, AX = 8760h

  40. Divide Overflow • If the resulting dividend is too large to fit in the destination register, then this causes a CPU interrupy • I.e., your program causes an error and throws an exception to the operating system • Similar things happen if you divide by zero • We’ll study interrupts shortly

  41. Your turn . . . What will be the hexadecimal values of DX and AX after the following instructions execute? Or, if divide overflow occurs, you can indicate that as your answer: mov dx,0087h mov ax,6002h mov bx,10h div bx Divide Overflow

  42. Signed Integer Division • Signed integers must be sign-extended before division takes place • fill high byte/word/doubleword with a copy of the low byte/word/doubleword's sign bit • For example, the high byte contains a copy of the sign bit from the low byte:

  43. CBW, CWD, CDQ Instructions • The CBW, CWD, and CDQ instructions provide important sign-extension operations: • CBW (convert byte to word) extends AL into AH • CWD (convert word to doubleword) extends AX into DX • CDQ (convert doubleword to quadword) extends EAX into EDX • Example: mov eax,0FFFFFF9Bh ; (-101) cdq ; EDX:EAX = FFFFFFFFFFFFFF9Bh Your copy of the book may have an error on page 243: 9Bh equals –101 rather than –65.

  44. IDIV Instruction • IDIV (signed divide) performs signed integer division • Same syntax and operands as DIV instruction Example: 8-bit division of –48 by 5 mov al,-48 ; AL = 11010000b cbw ; extend AL into AH mov bl,5 idiv bl ; AL = -9, AH = -3

  45. Example: 32-bit division of –48 by 5 mov eax,-48 cdq ; extend EAX into EDX mov ebx,5 idiv ebx ; EAX = -9, EDX = -3 IDIV Examples Example: 16-bit division of –48 by 5 mov ax,-48 cwd ; extend AX into DX mov bx,5 idiv bx ; AX = -9, DX = -3

  46. Example: var4 = (var1 + var2) * var3 ; Assume unsigned operands mov eax,var1 add eax,var2 ; EAX = var1 + var2 mul var3 ; EAX = EAX * var3 jc TooBig ; check for carry mov var4,eax ; save product Unsigned Arithmetic Expressions • Some good reasons to learn how to implement integer expressions: • Learn how do compilers do it • Test your understanding of MUL, IMUL, DIV, IDIV • Check for overflow (Carry and Overflow flags)

  47. Example: var4 = (var1 * 5) / (var2 – 3) mov eax,var1 ; left side mov ebx,5 imul ebx ; EDX:EAX = product mov ebx,var2 ; right side sub ebx,3 idiv ebx ; EAX = quotient mov var4,eax Signed Arithmetic Expressions (1 of 2) Example: eax = (-var1 * var2) + var3 mov eax,var1 neg eax imul var2 jo TooBig ; check for overflow add eax,var3 jo TooBig ; check for overflow

  48. Signed Arithmetic Expressions (2 of 2) Example: var4 = (var1 * -5) / (-var2 % var3); mov eax,var2 ; begin right side neg eax cdq ; sign-extend dividend idiv var3 ; EDX = remainder mov ebx,edx ; EBX = right side mov eax,-5 ; begin left side imul var1 ; EDX:EAX = left side idiv ebx ; final division mov var4,eax ; quotient Question: Why no “jo TooBig” in the last two examples?

  49. Your turn . . . Implement the following expression using signed 32-bit integers: eax = (ebx * 20) / ecx mov eax,20 imul ebx idiv ecx

  50. Your turn . . . Implement the following expression using signed 32-bit integers. Save and restore ECX and EDX: eax = (ecx * edx) / eax push edx push eax ; EAX needed later mov eax,ecx imul edx ; left side: EDX:EAX pop ebx ; saved value of EAX idiv ebx ; EAX = quotient pop edx ; restore EDX, ECX

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